脱氢
沸石
催化作用
化学
乙醇
铜
纳米颗粒
BETA(编程语言)
无机化学
化学工程
乙醇燃料
多相催化
吸附
核化学
材料科学
分子筛
有机化学
作者
Shiyu Xia,Mingyu Wan,Zhong‐Pan Hu,Zhiqiang Qiu,Junyu Liu,Jingfeng Han,Yue Zheng,Xiaozhi Su,Yang Zhao,Feng Xu,Chengcheng Yi,Wenfu Yan,Anmin Zheng,Y. G. Wei,Zhongmin Liu
出处
期刊:ACS Catalysis
[American Chemical Society]
日期:2026-03-31
卷期号:16 (8): 7356-7366
标识
DOI:10.1021/acscatal.5c08449
摘要
Ethanol dehydrogenation to acetaldehyde represents an efficient pathway for ethanol valorization, capitalizing on the versatile utility of acetaldehyde as a key chemical intermediate and the inherently high atom economy of the dehydrogenation process. Copper (Cu)-based catalysts have demonstrated good catalytic activity in this reaction. However, their practical application is hampered by insufficient long-term stability, and the nature of the active sites under operational conditions remains ambiguous. Herein, we report a rationally designed Cu-Beta zeolite catalyst where isolated Cu atoms are anchored within silanol nests of a dealuminated beta (deAl-Beta) zeolite framework, forming well-defined {(≡SiO) 2 Cu(HO–Si≡) 2 } coordination sites. These isolated Cu species undergo spontaneous self-evolution during the reaction or H 2 reduction conditions, transforming into confined Cu nanoparticles (2–3 nm) within the zeolite mesopores. The Cu nanoparticles are stabilized through zeolite confinement and interfacial Cu–O–Si interactions, exhibiting substantial catalytic performance with 85% conversion, 95% acetaldehyde selectivity, and stability exceeding 200 h (weight-time yield of ∼1570 mg g cat –1 h –1 ). Combining in situ XAS, in situ IR, and DFT calculations, we revealed a stepwise reaction mechanism involving sequential O–H and C α –H bonds of ethanol, followed by H–H coupling, all facilitated by the confined Cu nanoparticles. This study highlights a strategy of in situ active site self-optimization through reaction-induced nanostructural confinement, establishing an effective paradigm for designing highly stable and efficient heterogeneous catalysts via dynamic structural evolution.
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